THE APPLICATION OF ULTRA-ACOUSTIC METHODS IN THE PRACTICE OF PHYSICOCHEMICAL INVESTIGATIONS

Declassified in Part-Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 Declassified in Part -Sanitized Copy Approved for Release 2012/04/09: CIA-RDP82-00039R000200090002-9 Pra~+t'.i ce Of The ication of ph~~s~ r~chemical Tnvesti~ation~ by B. B. Kudryavtsev lJspekhi Khimii ,Progress of Chemistry? Vol XVZT, No z, pp 15$-173, Russian (article) Vol bi-mo per, Mar/Apr 194$  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 APPLICATION O UL11TASQNIC rjk~QD TO THE PRACTI ~a OF PH'SICQ cHi :[ CAL SEAR 4 B. B. Kudryavtsev (Moscow) Until comparatively recently, acoustics was conside ed a coma pletely investigated field of physics. It seemed that work in the field of acoustics could develop only in the direction of making more precise what is already known. It was difficult to visualize the possibility of new :fundamental discoveries in this seemingly well investigated field. And yet, acous- tics underwent a renascence, literally before our eyes. Discoveries, which expanded immensely the field of acoustical re- search followed one after another. This brought about a situation where papers on acoustics, which up to then had appeared only rarely in speci- alized physical journals, began to appear extensively in physico-chemip cal, chemical, biochemical, technological, biological, and medical journals. The revival of interest in acoustics is due, first of all, to the discovery of new sources of acoustic vibrations, which made it possible to obtain vibrations of frequencies and strength entirely differ- ent from. what was possible earlier. Strong acoustic vibrations of high frequency are called ultrasonic, these possess characteristics which are distinct from those of ordinary sound, It was established that ultrasonics are capable of producing chemical transformations, possess a strong dispersing and coagulating action, affect living substance; and seeds of plants, produce specific soimd-lumineSceIlCe, etc. it is precisely these characteristics of ultrasonics which attracted the attention of investigators whose interest lay in the fields of natural science contiguous to physics. The investigation of ultrasonics brought about the development of experimenthl methods Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09: CIA-RDP82-00039R000200090002-9 addition, the methods developed far making ultra" for their study. In a terized by expe~^a.mant. simpl;tcity' and h~.gh sonic measurements axe char c accuracy of results. Quits naturally, an attempt was made to utilize a moans of physico?~chemical inquiry into the ultrasonic measurements as different properties of materials. t the present time, ultrasonic rooted in the practice of various research measurements are firmly laboratories. It would be desirable to give a brief review of the possibilities which are introduced by ultrasonic measurements into the practice of research. The solution of this problem is the pur" physico-chemical pose of this paper. At. the present time, piezoelectric and r ag netoconst'-coon trans- ~ ducers are used to produce ultrasonics. Of the various piezoelectric materials (quartz, tourmaline, acoustics, quartz is used almost exclusively Rochelle salty used in for the preparation of transducers. stalline modification of 5i02; it crystallizes Quartz is the cry artz crystals possess piezoelectric character- in hexagonal syngony. Qu ca able of being charged by deformation and istics, i.e., they are p . n. The sign of the charge which occurs on the surr def ormEd by charge g? kind under compression and of the apposite face of the quartz is of one kind under tension. In order to obtain ultrasonic vibrations from quartz, it is cut into blanks of different shapes and dimensions, which have a definite orientation with regard to the crystallographic axes (Figure l)? The emissive surface is covered with a layer of metal (usually Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 n a,rzvestigating he propganon of ultrasonics in uses, the a I. charge to the rear surface of the blank. F?gure 1. Quartz crystal and quartz blank cut out per'- aendicular to the electrical axis The ank is pasa.'t~~oned on a po~r~rshed metal base sily~ r) ? fhe quartz bl e time as the electrode for feeding the which serves, at the sam , c the propagation of ultrasonics in gases an In a.nvestigatin ?;; laced directly in a vessel filled dielectrics, the q~;~artz blank a. p (2) In worltin with subst~:nces which can- with the test substance ? . , . ,.t is separated. from the substance under duct electrlc:~ty, the quay z rove s ti ga ti on wi th the aid, of a thin membrane. In the ].after case e uartz need not be covered with metal; the emissive surface of th q - instead, a membrane can be used as the electrode for feeding an al ernating potential to this sur:Eace of the quartz. t Contact ?tki metal covered surface of the quartz' blank is w a. aid of a compressian springy, although, in accomplished with the ? and ver important problem is solved by general, this practical ~ pending on the special f eaturE,s of the work. different methods, d.e, ~~ r which feed the alternating potential to the The electrode e connected to the electramanetic ogillatar as quartz blank ar .,.M?BmiWNgq';wf"klRM/"M~`~~~ }MI',w P M1 r^ ,d shown in Figare 2 ~\ Tr -7r 7777 re2 Diagram of piezoelectric transducer with an - artz blank; 2 - reflector of the interferometer interferometer. 1 qu ' 4 I t~i)7, 'P{~':. rrrgK 4yrif LtA~,~~' 1 ~'Ja~~2'tYU~N'rYt ~mrYJlii "rl r i r ~ k r d a i r` p rl r r U ,{i i,x?. rirl 1 P r s ~ ~rl~~M~ l ~1 MruTMi" ~ 4 'y , 3.jW~ .t.,,.l 7: ,,.k... ~~. ,r?, wr: -au ~p:vV AT '!,'r,i 'Ndl ra r J r? rt y 'u I '?. r+::,f v. ;jy r ,4, , r.. i ! r 7 ,,?4{ ~`,r 1tr Frr'.,,{,, rl 1~'. oa, y~',~~dr: s ,~~,~~~, 4r. Jx,17 , ,+ ~a{ ~~rJ ~; ,~~rt~, I , ~i? a4 t ;r~' , rt, ,a r ~,r ~I,i,,~ y. u. La.. pfd. L~, '>j wi..,. 1 r,.., 1 .,,.r,la~4~.1b !`~.. 9~1 ;tY tl..~ '4 r. 1~4A4 rel'. ,., don, 'It ~~ ~,?4~. y"P~ m~k E~ 1r i ?:r f', f P ~?!-., it r ~ '.' ,4 ~ ?.,r!. i n, ~ ~,l l~o,yr M1,ST, n rPy~ . q 1 N .} ~J ..V ~ n !N,,r'~ r.h,}! ) 'h:~d ,. aa, k'. r.a ., s ,;'frti !r rb ;1 ,ftP ~Y,,.ft ti~r~ . r d{ r , r,k ~ ~.~~, p ,~I>c d,~,~, "~~ ~d~,ryl,r,~!t.e+r,'b ,. ~,CI` v ~.ntl/~...~r.Ju? 1~P~'?.~: ~Nnlr ~ ,M1,....~,~~t L_. ~..... :~ ~ ~. I ~~.,, l ,.?.: _,.., ,,.. ~Py~, , s~, l~w~ 41 rrj ~ ~ ~'~~s. A~~~.?!?,..h ~s? r.~ .>si~3..~~ t~ 1~,4 ~,~prrr?h ~. { ' or?s.?1 Declassified in Part - Sanitized Copy Approved for Release 2012/04/09: CIA-RDP82 00039R000200090002-9  Declassified in Part Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 oscillator is adjusted to a frequency corresponding to the basic frequency off' tha natural vibrations of. the quartz blank; in working with liquids, the quartz can be excited also at the highest harmonic fr uen~ ties. In order to obtain the very strong ultrasonic vibrations necessary .for investigating the dispersing action of ultrasonics, the quartz is mounted in a separate vessel filled with a liquid which has insulating properties, while the substance under investigation is placed in a thin- walled vessel, which is placed in the insulating liquid, above the oscillating quartz. In acoustic practice, magnetostriction transducers are used in addition to piezoelectric transducers. The magnetostriction effcect consists of varying the dimensions of ferromagnetic bodies during mag- netization and demagnetization. By subjecting a ferromagnetic rod to the action of an alternating electromagnetic field, we can compel it to change its dimensions with a frequency which is equal to double the frequency of the superimposed field. Besides, resilient vibrations will occur in the substance adjacent to the rod. Pure iron is of little use for making magnetostriction transducers because of its very small magne tos tri cti on effect. Nickel and various alloys of nickel with iron and chromium possess a large magnetostriction effect; these are used for making transducers. The diagram of a magnetostriction transducer is shown in Figure 3 The magnetostriction oscillator L is' placed in the coil M, which is connected to the electromagnetic oscillator; the rod L protrudes directly into a vessel filled with the substance which serves for the study of the propagation of ultrasonics. Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 re 3~ Magnetostriction transducers M ? coil; L ? oscillating rod One of the advantages of magnetostriction transducers is that it permits use of rods of any desired diameter, which is often of im- portance from the point of view of design. A disadvantage of the mag? netostriction transducer, is the rapid heating-up of the oscillating rod, which causes a change in the dimensions of the rod and, consequent- ly, a change in its natural frequency, resulting in non?coincidence of the vibrations in the transducer. In investigating the properties of a substance with the aid of acoustic measurements, it is possible to determine either the speed or the damping of the ultrasonics in the given substance under given condi bons, The experimental determination of the speed of propagation of ultrasonics is considerably simpler than the detennination of damping and can, as a rule, be accomplished with much greater accuracy. In considering the possibility of applying acoustic measure ments to the practice of physico-chemica1 research, we shall limit ourselves to those problems in which the experimental phase consists of the determination of the speed of ultrasonics. The speed of ultrasonics in gases, liquids, and solids can be determined by different methods. The speeds of ultrasonics in gases are determined almost ex~ C lusively with the aid of an acoustic interferometer. In the acoustic interferometer, a polished metal reflector, capable of being displaced in a direction perpendicular to the surface of the quartz, is posi- tioned parallel to the emissive surface of the quartz blank, Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 The ultrasonic wave, which is emitted by the quartz, reaches the reflector, is relocted from it, and agairx strikes the surface of the quartz. Upon striking the surface of the quartz, the reflected wave off e cts the ope ra ting cond. tions of the quartz. The magna. tude of this influence can be evaluated in different ways . The simplest method of registering the action of the reflected wave on the quartz is to record the magnitude of the component constant of the anode current in the oscillating circuit connected with the quartz.. Variations in strength of anode current are measured with a sensitive galvanometer which is connected so as to gave a compensating circuit. During the smooth displacement of the reflector, the magnitude of the reaction changes periodically, reaching a maximum when a whole number of half waves is fitted in the distance between the quartz and the reflector, In Figure ~, the dis Prance between the quartz and the reflector is plotted along the abscissa. and the strength of anode current I in the circuit is plotted along the ordinate. Having de- terniined the distance between two adjacent maxima or minima and know- ing the frequency of the vibrations of the transducer, it is possible to determine the speed of the sound in the substance under investigate ti. on. Ordinarily,, de termination is made of the distance which con' tains several tens of maxima, which increases considerably the accuracy of the method. The error in determining the speed of sound by this method is usually of the order of tenths of one percent. Figure Li.. Variation of the strenh as a function of the distance current ,04 quartz blank and the reflector of the 0' Declassified 11 n d"r ~ the anode' 'E uF between the\.. 6 b Cp 4 ~ f ~ 1 I I interferometer? , I \ J\ 1 I L J y1ypy~wwkJUetm~pw+114wawM ?/+?~rwh1;:Mwww~NP~1i0RwPtbW,vr1%1 '? 110 nart - Sanitized Copy Approved for Release 2012/04/09: CIA-RDP82-00039R000200090002-9  Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 Recently, optical methods have come into wide use for deter" mining the speed of sound in liquids. The diffraction of light in an ultrasonic grating is used mosey for this purpose. During the propagation of an ultrasonic wave in a liquid, al- ternating compressions and rarefactions take place. Due to the rela" tionship between the coefficient of refraction off' he liquid and its density, periodic changes in the density of the liquid are accompanied by periodic changes in the coefficient of rarefaction. This holds ~' A true for both standing and passing waves. Thus, if an acoustic wave is produced in a liquid contained in a transparent, plane-parallel cell, the cell will act as a quasi.diffrac- -ion grating with respect to the light ray, Besides, the length of the sound wave will act as the constant of this grating. In determining the speed of sound by this method, a system, such as that shown in Figure 5, is assembled. Light from the source L (usually a mercury lamp) is focused by the condenser C on the narrow slit S . r1he divergent beam coming from the slot is made parallel by the objective Di. A cell Cq filled with the test liquid and contain- ing a quartz blank, is placed in the path of the beam of parallel rays. The long focal objective 02 focuses the rays on the screen Sc. if the quartz is not excited, an ordinary image of the slit will be seen on the screen. If the quartz oscillates, then, in addition to the basic image of the slit, easily visible patterns of the 1st, 2nd, 3rd, and sometimes higher order are also seen on the screen. When making actual measurements, the diffraction pattern is usually photos 1phed. Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part-Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 Declassified in Part - Sanitized Corv Arroved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 m for obserV'i the difxactbon of Fi ace Jw Axrangemant o~ syste avoS= L M Lamp; C condenser slit; light in ultrasonic w vee. 0 ? ce~.~. with quartz; Sc ? screen p1 and 02 w object~. , q distance between the diffraction images Having; determined the or c dimension) of the system, it is ' the slit and knowing the ge ome try. possible diffraction grating. ~sible to calculate the constant of the a w ' ffractian grating, in thi.s case, cartes Since the canstar~t of the ~- uency the sound X a then9 know~.ng the freq ponds to the wavelength of the sound quartz, we can determine the speed of of oscil1at~ons of the ~ this from v The error in determining the speed of sound the order of tenths of one percent method is usually of In addition to the above described method, there are many other ng the speed of sounds some of these are optical methods for me asuri ~ 5 of different methods can be found in mona Very accurates Descriptian graphs an ultrasonics ()). sound in solids can be accomplished Measurement of the speed of (6)e test specimen is cemented, to a pro by the f al.lowa.ng method f Th his provided with electrodes. The re~ perly cut quartz cylinder whl. c s connected to. the electric circuit suiting.composite transducer ' ~ is connected in series with an ohmic shown in :Figure 6? The quartz 1 r oscillator of constant ampliM tome netic esistance and ~~.th an elect g ,  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 2 The current f ~.ow~.n through the quartz tulle and variable rvariable frequency ~ ahrn~ am va~.taneter 3, connected. in parallel th an is measured nth a lamp ~ ~ of the is rsast,ance' The current strength aharactarizes the amplitude the ~~artz. The frequency of vibrata.ans is me ehani r,F~l vibra ti ans of ~. b the method of beats; also, a second source measured very accurately y ansducer l~ having a quartz stabilized frequency of vibrations is the tr and h. By series with the two multscil~lators and connected In ' ssible to measure changes in, current and, utilizing this system, it is po brata.ons of the complete transducer with consequent.y, ampln.tud:es of v' ~ ~ these measurements, it is possible to deter? changes in frequency. GJith mine the frequency of natural vibrations of the composite transducers natural vibrations of the individual quartz, of Knowing the frequency o.C alculate the frequency of natural vibrations it is not difficult to c of elasticity. Can the basis of of the test specimen 9 and its modulus Of it is possible to calculate the speed of the theox"y o.~ vibrations, sound in a marteal if ' ' ' is modulus of elasticity is known By this ra. ~. ea.sure the speed of sound in solids with an method it is possible tom ~ ' ~ :' ~. to 0.Q1 percent. ... "".~t ,. acy o f p u --'? ,. actor .{?,~ .,~?a T ? , Figare of stem for dete:cm~.ning the speed of ultra 6~, ,,rran~ement ~ ? ,~ uartz rod; 2 -variable frequency oscil~ sonic, waves in sola.ds, l q r. a quax~tz~stabilized transducer of 100 ~_ator; 3 ~ lamp voltxf~ete , ~ or of 10 kilohertz; 6 ? multioscillatar of kilohertz; ~ - multioscillat and arrtplif'ier; 8 ? laud speaker; 9 -test l kilohertz; 1 ~ detector spe cimen In presenting an exposition of the possible ways of utilizing or ur ores of physica_cherrlical research, it ultrasonic, measurements f p p a plicatian for the study of is natural to start with their earliest p f~ the cal.l~.s~ons the elementary processes of the exchange of energy during pr ..,. A r.~;.:, t...., . .. ,..,.. .: 1~,~ 6l. . .rl. 1.. h b f .?,} a r! I, I /, n f,~ Ey ~+E,.d, 1171. It. I 1 ' S 4yH k1 .J sl f I f t ! I 1 Y 1 I: ~ 1 Declassified in Part - Sanitized Copy Approved for Release 2012/04/09. CIA RDP82-00039R00020009t! ~Y ht ~ X11$ l I y J t7 '~ t I ~ YI ,II fw1 ~ua>?~~ l I.ll._." ! I ! 0002-9 IIItI ':  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 or gaseous molecules, This becarae possible in connection with the study of the dispersion of ultrasonics in gases. As is well known, the speed of ultrasonics in polyatomia gases depends on its frequency. At the present time, dispersion is usually explained on the basis of the so''called relaxation theory. On the basis of the hydrodynamics of compressible liquids, the speed of sound v is expressed by the e qua ti on (1) where p is the pressure, is the density, and is the ratio of the heat capacities c ~cv~ In its turn, cv is the partial derivative P of the internal enemy" with respect to the temperature. The internal energy of a gas is distributed equally among the different degrees of freedom which the molecules of a gas possess. In a polyatomic gas, a portion of the internal ener}r goes into translational and rotational movement of the molecules and another portion goes into vibrational degrees of freedom, Ordinarily, the heat capacity cv of a gas is divided into the external heat capacity c which depends on the external degrees of freedom, and into the in' a' ternal heat capacity ci, which depends on the internal degrees of free f dom. During the alternation of compressions and rarefactions which take place in a sound wave, the additional acoustic energ~r which is supplied to the molecules is at first stored by the external degrees of freedom and only after this does it partly change into vibrational energy. The fact that the establishment of an equilibrium distribution of energy between the external and internal degrees of freedom requires a finite time interval for compleon is of fundamental significance for the theory of relaxation. By increasing the frequency of sound, a .10 Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 Frequency rec.an is sooner or later reached, in which the proeess of establishing an ener equilibrium is not in phase with the process ure . A pha"e difference takes place between the of varying the pr ss phase and the e qua. a.ib rium dis'~ prssure phase and the intFrna:l enemy' tribution of energy is disrupted. At a sufficiently high frequency, all acoustic energy is in sufficiently farm of kinetic enery of translational and rotational movement of the molecules. This is equivalent to a decrease of the heat capacity of the gas to a l value c. At a sufficiently low frequency, the limiting a as will have the second limiting value c ? Be~ heat capacity of the ~ v values of frequency there is a region in which tween the two extreme the as depends on the frequency of sound. Ob- the heat capacity of viously, is, at the same time, also the dispersive region ~.ously, this region of sound. Actually, if we plot the experimentally determined values of the speed of sound in a pofyatomic gas as a function of the frequency, we obtain a characteristic dispersion curve. Figure 7 shows a similar curve for C02; the logarithm o d along the abscissa and the speed of sound the frequency is plo~,te r1 ifi l ,.._., ... , along the ordinate. Figure 7. Dispersion of the speed of ultrasonics -- .~ v C On the basis of theoretical considerations, the frequency o which corresponds to the point of inflection and determines the disp ersive region, can be expressed by the equation p Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA RDP82-00039R000200090002-9 (2) is the average 1i1'e of the excited quantum. By proper de" where ent of the theory, it is possible to take into account the velopm presence of two or more vibrational levels (7,8), It is expected that the excitation of the vibrational state of the molecule during collision OCCUrs only in case one of the colliding molecules possesses an increased reserve of energy or, in other words, a certain activation energy of the excitation process of the there is vibrational state. In this case, a detailed study of the relationship between the speed of sound and the ?Lemperature makes it possible to undertake the experimental determination of the activation energy of the vibrational process (9). Thus while investigating the dispersion of sound in pure gases and in gas mixturess it is possible to determine the following characw teristi-CS of the elementary processes in the gases probability of excitation of the vibrational state during 1. collisions of the gas molecules, effectiveness (in the. sense of the excitation of the vibra- 2, signs between different molecules (10,11). tional state) of colli Hence, it is possible to attempt to explain the observed considerable difference in the effectiveness of the impacts of different molecules. Ascertain the presence of one or several vibrational levels of the molecule 7' 8) r 1.. Determine the activation energy of the excitation process of the vibrational state of the molecule. cv . Declassified in Part - Sanitized Co A roved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 ? Calculate the average life of the vibrational quanta ( 12), ~ As an example, the probabilities of energy transfer from the impact of the internal energy of the CO2 molecule to molecules of other uses, as determined the acoustic method, are listed in Table 1 by Average probability Mixture Cot - CO2 CO2 - N2 CO2 -He Cot H2 Cot - H2O everran,er TABLE1 Possible reaction 002 + CO2 ~ + 2C0 + 02 002 + N2 -??4 CO + N20 CO2 + H2 --* C0 + H2O Cot + H2O -+ H2 CO3 On the basis of the data in Table 1, it can be concluded that the probability of the loss of a vibrational quantum by the CO2 mole cute depends greatly on the characteristics of the molecule with which it collides. It is clear, from what has been said, that the investigation of the propagation of ultrasonics in different uses and gas mixtures a valuable method of studying the elementary processes of the re?is distribution or energy during collisions of gas molecules. However, another entirely different use of acoustic measurements for studying elementary processes in gases is possible. If it is assumed that gas represents an aggregate of molecules moving independently of one another and that the reaction among them of Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 the co11i5ian time of the moleces, then the is limited only by speed of pxopara~an of the acoustic impulse in such a mechanical ~ ystem should, of necessity, coincide with the average speed of s movement of the molecules, ally observed difference between the speed of The experiment and the speed of sound. can be explained by the molecular movement penetration of the molecules into one another for some time instead of rebounding instantaneously during collision, i.e., the existence of a finite collision time is considered probable. With such an in- ' terpre totion of the propagation of sound in gases, it is possible to utilize acoustic measurements for determining the collision time of molecules of different gases it is quite natural to consider which cause vibration of molecules, as partic- effective collisions, In this instance, the dispersion of sound is ularly protracted. associated with the non coincidence of effective collisions. The measurement of collision time is of interest from the point of view of chemical kinetics since it furnishes information for calculating the number of triple collisions. One of the first applications of acoustic measurements for the i?nvestigation of the properties of liquids was in the study of the contraction of different liquids and mixtures of liquids. Considering sound and the contraction of the medium are related that the speed of by the e qua ti an f3) where is the density of the liquid and is the coefficient of the adiabatic contraction, it is possible to determine the latter by de- ~.c contr 90002-9 Declassified in Part - Sanitized Copy Approved for Release 2012/04/09: CIA-RDP82-00039R0002000  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 termining experimentally the speed of sound v, Measurements ob". tamed with binary mixtures revealed anomalous contractions in a number of cases, Thus, V, V, Tarasov and his coworkers who investigated the contraction of mixtures of ethyl alcohol and water, discovered the anomalous contraction of the xriixture containing approxiM mately 25 percent alcohol, The results of these experiments are shown in ~Tigure 8, in which the contraction of the mixture is plotted along the ordinate and the percent alcohol in the mixture along the abscissa, ,tt (3 10~ crn2~~~_ f Q/L ~~.gure 8. Contraction of a mixture of water and ethyl alcohol The study of similar anomalies makes it possible to conclude that, in mixtures of liquids, compounds are formed between the comr ponents of the mixture. In, this manner, I. G. Mikhaylov, who inves- tigated the speed of sound in mixtures of formic acid and water l5} came to the conclusion that there are two compounds of the acid with the water. In one compound, the water and formic acid are in equip molecular amounts, but in the other compound, there are two molecules of water for each molecule of acad. Similar investigations came into considerable use t l6) because they supplement the stud of the me ~' Ming and boiling curves of binary liquid mixtures. Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanzed Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 In the caso of solutions of electrolytes, the electrostatic field of the ions changes considerably the contraction of the water in the immediate vicinity of the ion. In practice, the variation of contraction is limited to several layers of water near the ion. By measuring the contraction of solutions of electrolytes, itis possible to characterize quantitatively the layers of solvent near the ion, which have strongly changed properties. Considering that the contras tion of water in the immediate vicinity of the ion is extremely small and that the inner pressure caused by the field of force of the ion is great it may be assumed that the ion is surrounded by a certain "non' contracting'" volume of solvent. If the '"non contracting" volume is identified with the solvate sphere, then it becomes possible, on the basis of acoustic measurements, to determine the solvation of different ri ions l The solvation numbers of certain ions, as determined by the acoustic method, are listed in Table 2. Recently, this method was used to determine the solvation of various high molecular compounds, e. g., gelatin in pure water and in solutions of different pH, nitrocellulose, acetylcellulose, and ethyl' cellulose in acetone, etc. X18) 'I'bis investigation emphasizes the experimental atcantages of the acoustic method of determining solvation; the only disadvantage noted is a certain arbitrariness of theoretical assumptions which form the basis of the calculations, -16.. R',4' Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 TABT1 2 ion ~al.vati.Qn Numb ~ ? Na Mg Ba Be Al Cl In 19~.p Rao ~l'9) established the empirical rule, according to , which the product of the molecular volume and the cube of the speed of sound is not dependent on the temperature L. V.3 M l 6 a"1 V. 04) In this exPressian, M is the molecular weight, is the density, and V is a magnitude independent of temperature and is usually called s the speed of sound". This relationship was checked with a large ~s a mol r number of experiments and V remained a perfect constant in practically cases under investigation. Sometimes, this rule does not all the strictly hold; in particular, deviations from this rule are observed in the cases of water, metby1 alcohol, and acetone. There is a view- point, according to which the failure of V to remain constant in these 11 Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA RDP82-00039R000200090002 9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 cases is explained by the molecular association of the corresponding (20) es in the liquid phase ; in this manner, the utilization subs tano measurements for investigating the formation of molecular of acoustic aggregates a. 'n liquids is made possible. By comparing the data of the obtained with the aid of Raman spectra, with the assoca.ata.an of liquids, data obtained with the acoustic method at different frequencies of sound, one may attempt to determine the life of molecular aggregates which occur in liquids. It seems to us, however, that these conclusions are based on an insufficiently firm foundation. As it turned out, the magnitude V is an additive function of the composition tion of the substance and, in individual homologous series, function of the molecular weight ~ 21} ? it can be represented by a linear In Figure 9, the molecular weight M is plotted along the abscissa and the corresponding magnitude V along the ordinate. As is obvious from an examination of the curve, the linearity of the variation of the magN n V with the molecular weight is perfect. The molar speed of ~.tude sound V can also be represented as an additive function of the bonds which are present in the given compound (22), By introducing the in? crements of the bond ( C ? c1 ? 230; (C : C) N 129; and (C 0) ? 186, it is possible to calculate V for different organic compounds, in perfect agreement h experimental data. Thus, for example, in the case of paraffins, the following formula was obtained: V (n ? 1)(~C + (2n + 2)(C ? H)? mdc ing use of the indicated property of the molar speed of By sound, it is possible to utilize acoustic measurements for verifying proposed structures of organic compounds. Declassified in Part - Sanitized Copy Approved for Release 2012/04/09: CIA-RDP82-00039R000200090002-9 (!)  L Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 V f Relationship between "molar" speed of , re 9 ,.,,1,/ ---- ~. and molecular weight of subs antes: 9 Qund ~, ~ man Qhydroxy a1~ l paraffins; 2 - acetates, 3 I ` cQhals L ? .. aromatic hydrocarbons, p ketones 20 , 0 For different members of one and the same homoa,agaus series, directly related to the parachor, molar the molar speed of sound is in the Van der Waal equation, molecular mag' refraction, constant b and critical volume 23) netic rotation, ar seed V is plotted along the abscissa u.re 10 s the mot. p In Fig the ardina to . There is a pe rf e c tly dire c and the parachor P along he arachor and V for individual hornolo~;ous relationship between t p seleso It was established empirically that the boiling point of a ^i ' n of the logarithm of the molar speed: substance is a linear :~unctlo . T+Blogv clue for different represdntatives of a where A and B have the same v ,. ous series. In this case too, deviations are noted definite homolag This i s shown by Figure ll, in which the for associated liqua.ds? different organic compounds is expressed as a func boiling point tb of d'~ us series consisting; of non associated Lion of log V. For :Liquids, the linear dependence holds trued 1304 Relationship between parachor and Fi re 10e speed of sound: lp aromatic hydrocarbons; 2- rdroxy alcohols; 3~ paraffins ~qa a .l9 .e. (6) "molar u mono: ~ LfOO oa Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 loo (70 /1 -L r ,(o 'o log V Figure 11, Relationship between boiling point and "molar" speed of sound: 1 aromatic hydrocarbons; 2' acetates; 3 w paraffins; L. monohydroxy alcohols On the basis of the indicated relationships, a new method of determining the molecular weights of high polymer compounds was pro- posed; this method is based on the simultaneous determination of the molar refraction and the molar speed of sound, ( 2).) The experimental complexity, together with some uncertainty of the theoretical bases of this method, gives little hope that it will find wide use, although in individual special cases, its use is quite possible. As was mentioned above, the speed of sound is related to the adiabatic contraction of a substance by a single value; in its turn, is related to the inner energy of a substance U by the following a~ U f - V? avz raw ( 7) ified in Part - Sanitized Co  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 where v is the volume. Tf we accept as a working hypothesis the determination of the liquid first proposed by Hrilouin (2) and Born liquid state, which was arid in accordance with which the liquid differs from the corresponding solid by the lack of a modu:lu,s of shear, then it is possible to obtain an expression of the speed of sound as a function o;C the density of the liquid and of magnitudes which determine the field of force of the molecules (27), xf we assume that the inner energy of the liquid is essentially potential energy resulting fx m the interactiol of the molecules and, also, if in calculating the potential energ, we limit the calculations to the reaction of the molecules with their nearest neighbors only and ignore the reaction with more distant molecules, then it is possible to obtain C 2 7) the following equat:i. on for the speed ~. of sound ~PO-L S r,f (8) where r;is,the distance between the molecules,(r) is the potential energy of the interaction of two molecules, expressed as a function of the di stance between them, fD I s the density of the liquid, and is the second derivative of (r) with respect to r. Quantum mechanics makes it possible to determine the potential energy of molecular interactions (28). However, the calculations are so complex that it is preferable to use the approximate equation of Lennard-Jones, which is a good approximation, if the distances between the molecules are not too great (29), and yields results which are practically not different from those obtained by a strict quantum me- chanical solution, -.21- Declassified n Part - Sanitized Copy Approved for Release 2012/04/09: CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 According to Lennardr'Jones, the potential energy of two atoms or molecules ? (r) can be expressed by the following: Q() where r is the distance between the atoms and 7, , /.i' , n, and in are constants. L'ennardMJones calculated the values of A and, using n t 12 and m 8 for helium, argon, hydrogen, and nitrogen X34) (9) The possibility of calculating the speed of sound, in liquids, on the basis of the name ri cal values of constants which determine the potential field of the molecules and of intermolecular distances, is of considerable interest. Therefore, it would be desirable to verify the agreement between the results obtained by equation (8) and those obtained by experiment. Such a comparison was first made for the speed of sound in liquid nitrogen, hydrogen, and helirn9 in calculating the intermolecular distances, it was assumed that the particles of simple liquids form a cubic face-centered lattice. The speeds of sound in nitrogen, as calculated from equation ( 8) and observed experimentally, are listed in Table 3. The presence of two numbers in the column of the calculated speed of sound is due to differences between the densities of liquid nitrogen, as cited in the literature, [See next page for representation of Table 3] Considering the characteristics of such a comparison, the agreement between theory and experiment can be considered as quite satis- factory. -22- ified in Part - Sanitized Co  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 TABL'~ 3 ~x e~.menta~.~.y determa,n~d sped urea in Calculated speed of pound' p Temperature, off' sound a,n meters~se~d ,.~ In meters aecond ,,,. d~ree K 869 , 8i ? 826 ~ 889 678 ?. 861 ? 909 72 910 M 8914 929 70 92 _ 929 de tees Kelvin, the calculated value For liquid hydrogen at 24,3 g which is in close agreement with the of v is 1006 metes per second, experimentally observed value of 1127 meters per second. ~?1 values of v for liquid helium at 'the calculated and e xpe rimen d 2 meters per second, reSpeCt~.vely. decrees Kelvin are 270 an Recently, Jaffe calculated the values of the constants in the ' ous liquids; at the same time, he also :Lennard-Jones equation for vary ~;?;e intermolecular distances in the corresponding calculated the aver the speeds liquids at their boiling points. With the aid of these data, of sound listed in Table ) were calculated. eorand experiment can be considered as The agreement between th Y - - it is conside~d that the calculated lower satLsf:actory', especially, ' ~-~ ~ a' ned b the disregard of the kinetic energy speed values can be eXpl 1 Y in cal,cuating the inner energy' of the liquid. ~. It seems to us that, in the future, acoustic measurements will tud in the fields of force of molecules. find use as a method of s y g e in the solid state, acoustic. methods In investigating a substanc 'A Arrr Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 TABLE Subs tan ce Calculated speed of sound, in meters second Experimentally deternl.ried speed of sound, in meters second. 1032 1009 Acetone Carbon disulfide 9 61 10Th 711 ' 860 Chlorof o~n Carbon tetrachloride 61.6 7~a 069 93~ Ethyl ether aL.2 1030 Benzene Ethyl alcohol 1030 laoa 1L66 lS;a Water make i t pos sible to study the thermal. chary cte ris tic s of the solid, the variation of magnetic properties with the temperature, the plasticitY, the phase changes in solids, etc. In the case of ferromagfletic substances, the elastic and magnetic properties are interlocked because of the magnetostrictJ.on; for this (32) was used for study ? reason, the composite piezoelectric transducer the elastic and absorbing characteristics of inp ing the variation of divn.dual crystals and polycrystalline crYstalline specimens of nickel as a function of the intensity of magnetization and temperature. The alloy o copper and gold, G`u3au, upon being cooled graduallyof forms cars tals with a cubic lattice,. Upon raising the temperature, the re galalvity disappears and, above 390 degrees the alloy changes into a solid solution. In ~ '"gare 12, the temperature is plotted along the chief moduli of elastici of the crystal with abscissa and the three a cubic lattice are plotted along the ordinate. Declassified in Part -Sanitized Coy Approved for Release 2012/04/09: CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 Figure 12. Variation of the modulus of elasticity of an I individual crystal of Audi as a function Hof temperature 2 From the variation of the elasticity of the alloy with "the 'degree of regularity, it is possible to verify the th~o ataca1 conce t of the nature of the forces which act in the crystalline lattice of the solid '1. _ ._..F_ _ ~._.... _ too LAG By observing the variation of the modulus of elasticity of the solid near its critical point, it is possible to study the kinetics of transformations in the solid phase ~3)m An investigation was made of the variation of the modulus of shear in solids with rising temperatures, up to the melting points ~3}. The earlier investigations gave rise to the expectation that the modulus of shear will approach zero value gradually, as the melting point is approached. According to the theoretical concepts of Born and Fuert, the modulus of shear has a limiting value just below the melting point. In order to verify the correctness of these concepts, an investigation was made of the variation of the modulus of elasticity of crystalline NaCI in the immediate proximity of the melting point. In this investigation, the specimen of rock salt was cemented directly to a rod of fused quartz and the latter to a piezoelectric transducer. Such an a rrangement made it possible to place the specimen in the center of a tube furnace, in the region of uniform high tempera- Lure, while the vibrating quartz rod was in the cold section of the fur- nace. The latter condition was necessary since the quartz changes at 57; degrees from the < -modification into the J3 -modification which does not possess piezoelectric characteristics. i' Declassified in Part - Sanitized Copy Approved for Release 2012/04/09. CIA-RDP82-00039R000200090002-9  1 q7i/ r Melting point temperature Variation of the modulus of elasticity of crystalline NaC1 Figure 13 shows the variation of the modulus of elasticity of torsional vibrations of the NaC1 specimen at a temperature close to the melting point. As can be concluded from an examination of the given curve, the modulus of elasticity has, in accord with the views of Born, a limiting value just near the melting point. The general nature of the curve is in qualitative agreement with the developed theory, as a function of the temperature, near the melting point, The few above-mentioned examples indicate that acoustic methods can be successfully utilized for expanding our knowledge of the nat;are of the solid state of matter. Recently, ultrasonic methods have come into use in the investi'- gation of high polymer compounds which are acquiring greater indus trial importanGe (36,37) e If a concentrated solution o:C gelatin in water is subjected to of the action of an ultrasonic fief/medium intensity, then, after a short time, one can detect a considerable decrease in the viscosity of the solution. However, this change is reversible and, a certain time after the ultrasonic action has ceased, the original viscosity Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-09039R000200090002-9 of the solution is restored. The exp1anati.on of this phenomenon is that the anomalously large viscosity of the gelatin solution is caused by the mobile skeleton which is formed by the fantastic inter locking of the long, threadlike molecules of gelatin in which the soi- vent is retained as in a sponge. The indicated skeleton is held to- gether by relatively small Van der Waal forces, the energy equivalent of which is between 2,000 and 8,000 calories per mol of the bonding groups. Upon subjecting a solutioh to the action o.r' ultrasonics, cavita- tions take place; the Lormation o? these cavitations is facilitated by the air dissolved in the water. The cavitations which take place in the liquid under the action of the ultrasonic wave begin to pulsate and these pulsations are equivalent to microscopic jarring. It is pre- cisely this microscopic jarring which destroys the skeleton that was formed by macromolecules. The effect of pressure on the dispersion of ultrasonics can be regarded as direct proof of this viewpoint. The formation of cavitations is considerably hindered under a pressure of 10 atmospheres and, at the same time, there is practically no effect of the ultrasonics on the viscosity of the solutions. In this mariner, the reversible change in the viscosity of solutiohs of high molecular substances can be regarded as the result of temporary damage to the skeleton of macromolecules by the pulsation of the cavitations resul- ting from the action of ultrasonics. When the action of the ultrasonics ceases, the macromolecules, under the action of the Brownian movement, form a skeleton again and restore the original viscosity of the solution. It is possible to observe also an irreversible change in the vis- cosity of solutions of high molecular substances subjected to the acti. on of ultrasonics such a change must naturally be related to the decrease -27- Declassified n Part - Sanitized Copy Approved for Release 2012/04/09: CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 in the molecular weight of these substances. It was shown that, under the influence of an ultrasonic field with a frequency of 300,000 hertz and a strength of approximately 10 watts per square centimeter, the viscosity of solutions of nitrocellu- lose, polyvinyl acetate, and polystyrene decreases considerably and ir~ reversibly, thus indicating that a chemical depolymerization of these substances takes place. Figure 1L, shows the kinetics of depolymerization of three solu? tions of polystyrene in toluene at 70 degrees under the action of ultrasonics. At first, the molecular weight of the polymers, as de- tezrnined from the viscosity of the solutions, was 100,000, 10,000, and 300,000, respectively, After a two-hour treatment with ultrasonics the original molecular weight decreased to 30,000, 70,000, and Lj.0,000 respectively. It should be pointed out that the depolymerization is essentially completed in the first 20 minutes of ultrasonic action, Also, the polystyrene specimen with an original molecular weight of 10,000 was' relatively more stable against the dispersing action of the ultrasonics, This circumstance can be regarded as confirmation of the existence of macromolecules of different configuration but of the same chemical composition, In the given case, we are dealing with the action of ultrasonics only, and not with the result of the pulsation of the cavitations, because by increasing the pressure to 1 atmospheres in this case, thereis' observed an increase of the depoiymerization action under the influence of the ultrasonics. f ? f Q I 21\ Figure Depolyrnerization of polystyrene dissolved in toluene, under the action of ultrasonic', ""`w+.ounv+wn+w !~s~uwM7!aw nwie TY) f Y~ Declassified in Part - Sanitized Corv Arroved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 In prd?r to de to rrna.' ne the causes of the chemical depoi eriZatian~ those forces which are required to rupture the it is necassaty to know chemical bonds in the given compounds. forces necessary to rupture different chemi- The mar;na.tudes of the cal bonds are listed in Table 5 (38), TABLE .es er 1n d n .x.y-.~0,_.~. Bond Farce bondL2. l~) CC 1.~ x.77 co c = o 9.77 C 12.06 C 16,6 C ' C 17,2 The problem of the shape of the macromolecules is also of con siderable importance. According to recent investigations, the shape is intermediate between that of a stretched chain and that of a chain coiled into a ball. In the case of polystyrene with a molecular weight of 100,000 has a length of 3,000 angstroms and a diameter the stretched molecule of 6 angstrorns The ratio of the axes is equal to 500. In the case . in existence in solutions, the length is approxi- of molecules actually mately 1,S00 angstroms and the diameter 1~ angstroms, which corres- ponds to a.ratio of the axes equal to 100. Such macromoleces per movements in the solution and, in addition, Norm irregular internal are also gradually ally displaced as a whole. The movement of such a mole -29- Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 culey as a whole, is gradual, with an average spa cd off' O. S to 1.0 per second. Under the anfluenc? of the sound wave, the molecules of the solvent acquire speeds the maximum value of which, under the dLcated conditions, is approximately L0 7neteV$ per second. If it is asswned that the macromolecules, under the influence of the 1ari7e inertia, do not :follow at all the movement of the liquid ., caused by the action of the ultrasonic wave, then fraction will take place between the macromolecule and the solvent. The magnitude of the force of friction can be determined approximately. For the given case assuming that the force of friction is 102 poises), the Force of friction is of the order of 2 3 x 1O dynes. By comparing this value with those listed in Table , we see that the force of friction exceeds considerably the strength of the C - C and C - 0 bonds. If the calculation of the rorcee of friction is correct, then the polymer should depolymerize completely as soon as it is subjected to the action of ultrasonics. Obviously, the assumption that the macromolecules can- not follow completely the movement of the solvent is incorrect. It is probable that in individual cases sufficient friction will occur to rupture the chemical bonds. This circumstance explains the prolonged time necessary for depolymerization and the small degree of depolymeri~ nation. Discontinuation of depolymerination with decreasing molecular weight of the polymer can probably be explained also by this circum- Stance. In this manner, one can hope that the investigation of the action of ultrasonics on solutions of high molecular substances will make possible a better understanding of the nature and properties of this very important class of substances in the future. ..SON Declassified in Past.- Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 ~n thuds of ul?trasor~a.csa ? conclud~a.ng the rev~.ew of the me wh~.ch out the cor~t~.nuallY growin~ por~ance it is necessary to poin c~p~;ration in the ar on i acquirinry as a second u~.trasonic dispersion (3C) La) r phYsico~cher.Cal research ' prac . ~..ce o The In order not to exceed the e resent review is not exhaust~.v . ~ about p to say notha,n.~ ? Of the review, it was necessary reasonable ti~ata.an of the ka,~leM on of acoustic methods for the inve s the app:La.cat~.o tics ('-~1 the use of ultrasonics in research ~ o.~ chemical reactions labor (1 .~2 7 the use of u~.trasanics in atories of the cerarraa.c 1ndur ~ t cs , the detection of defects in metals the use of ultrasoni in ata.on with the acoustic iniaturc scale oiler colloid chemistry ~ aid of ultrasonics s etc. the ment:i. oned examples of the However, it seems to 'us that suz ficien'~ sin research practice is quite successful use of ultrason~.c Qf physico- ods at im aortance of acoustic meth to make clear the great ~ chemical research. ear future, lxltrasonic methods One should thing than ? ~n the n A C and will in physical chemical laboiatoriea will come into routine use different states better undersndin? the propert~.es in as us in .t. and the ?ans:Coxmation of matter durr~.ng physical laws which ~pVern the tx and chemical processes. Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 1. S. S. Urazovskiy, I, 0. Polotskiy,j,ek~ (Progress of Chem- istry, 19)40, 9, 88g. 2. 11, Kudryavtsev, ZhETF (Journal of Experimen.. ?tal and Theoretical Physics), 17~ 294. 3. Ostrovskiy, ZhTF (Journal or Technical Physics), 1937, 7, 2O3, Li.. L. Myamikov L, i"re an Sovrernenn e problezicheskoy akust,~.ki (Modern Problems of Physical Acoustics), ONTI (United ScientificsTechnical Press), 1935. a~. T3ergmann, Ultrasonics and Their Scientific and Technical Applications. 6. L, Balamuth, Phys, Rev., 1931.,>, 715; F. C. Rose, Phys. ltev., 1936, 249, 50. 7. w. T. Richards, J. Chem, Phys ? , 1933, 1, 863. 8. N. E. Rose, J. Chem. Phys, 1931., 2, 260. 9. W. J. Chem. Phys, 193!.x, 2, 206. 10. lvi. Metter, ZhETF (Journal of Experimental and Theoretical Physics), 1938, 8, 73L. 11. W. T. Richards, J. Chem, Phys. f 1936 9 )4, 561; 193)4, 2, 206. 12, A. Eucken, R, Becker, Z, phys. Chem., 19314, (13)27, 235. 13. 13, Kudryavtsev, Trudy I"JXhTI imkai Mendeleyeva (Worl(s of the Mendeleev Chemical Technological Institute of I~Ioscaw 19140, 14, V. V. Tarasov, V. P. Bering, A. A. Sidorova, ZbFKh (Jour nal of Physical Chemistry), 1936, 8, 372. 15. I. CL I"Jikhaylov, DAN (Reports of the Academy of Sciences), 1911, 31, 550. 16. P. Prozorov ZhF'Kh (Journal of Physical Chemistry), 19)O, 114, 391; P. Prozorov, V... Nozdrev, ZhET1+ (`Journal of Experimental and Theoretical Physics), 1939, 9, 625; I. Mikhaylov, DAN (Reports of the Academy of Sciences) 191 31, 3214; A. K. Dutta, B. Ghosh, Ind. J. of Phys., 19L3, 17, 19. l ~ ~ 7. A. G. Pasynskiy, ZhFKh (Journal of Physical Chemistry), 1938a lls 608, 18. Pasynskiy, Acta Phys. Chirn. URSS, 19147, 22, 137, 263. 19. Ramod Rao, Ind. J. of Phys.,190, 1L,, 109.  Declassified in Part - Sanitized Copy Approved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9 20. A. Wei ssler, J. Chem, Plays., 19L7, 15, 210. 21. itamo Hao, J. Chem. Phys, 1914, 9, 682, 22. R. Lagemann, J. Corry, J. Chem. ?hys?, 19L~2, 10, 759. 23. R. Lagemann, W. Dunbar, J. Phys. Chem,, 19L1$, Li9, L.28. 2L.. A. Weissier, J. Fitzgerald, 1. Hesnik, J. App1. Phys., 19L.7, 18, 1i.31i.. 25. Prilouin, Phys. Lev., 1938, 31i, 916. 26. Ia. I. Frertkel, Usp, fiz, nauk (Progress of Physical Sciences), 19)41, 25, 1. 27. B. Kud.ryavtsev, Dia (Thesis), Moscow, 19L~5. 28. R. H. Fowler, E. A. Guggenheim, Statistical rIlJiermow dynamics, 1939, page 292. 29. H. H. Fowler, E. A. Guggeriheim, a.oc. cit., page 291,.. 30. LennardwJones, Physica, 1937, L, 9L~1. 31. G. Jaffe, Phys. Rev., 1912, 62, L~63. 32. S. Siegel, S? uimby, Phys. Rev., 1936, 249, 663. 33. S. Siegel, Phys. Rev,, 19L.O, 57, 537. 31. S. Siegel, J, Chem. Phys., 19L~O, 8, 860. 35. L. Hunter, S. Siegel, Phys. Rev., 191.2, 61, 5iS. 36. B. N. Rutovskiy, Usp. khim. (Progress of Chem- istry), 1910, 9, 1395. 37. G. Schmid, E, Beutelmuller, Z. Elektro- chem., 19 3, 49, 32$. 38, H. Mark, ' J, .Acoi.i.stical Soc, A.mer., 19Lj5, 16, 183. 39. Solov' yeva, Ko11oidn. zh. (Colloid Journal), 1939, 5, 289, :i., 140. S. N. Rzhevkin, Ye. Ostrovskiy, Acta Phys, Chin. URSS, 1935, 721. L.1, B, Kistiakowsky, W. T. Richards, J. Amer. Chem. Soc., 1930, 52, X661, 1.2. G. Bole, G, Loomis, J. Appi. Phys,, 19L.3, 1L., 24L3. 1.i.3. S. Sokolov, Phys. 2., 1935, 36, T2. )i., K. Solder, Chem. Rev,, l9LlJh 3L4, 371. Las. S. Krechrner, S. Rzhevkin, Techn, Phys. UHSS, 1937, L1., IOOL~. E\1T Declassified in Part - Sanitized Copy Aproved for Release 2012/04/09 : CIA-RDP82-00039R000200090002-9